JP3919662B2 - Method for transmitting emergency call of mobile telecommunications equipment and mobile telecommunications network - Google Patents

Description

[0001]
The invention relates to a method for transmitting an emergency call of a mobile telecommunications device according to the superordinate concept of claim 1 and to a mobile telecommunications network according to the superordinate concept of claim 8 .
[0002]
In recent years, the possibility of automatically transmitting an emergency call other than manually dialing an emergency call number has been increasingly established in mobile radio networks. This service is referred to as an “emergency call” and establishes an automatic connection between the mobile telecommunications equipment and a so-called LCS client such as an emergency call center. For this purpose, for example, an automobile is provided with an accident sensor, which automatically triggers an emergency call (possibly after seeking a driver's response) when an accident is detected. Here, for example, when the driver is not conscious, the vehicle position must be specified. For this purpose, the UMTS (universal mobile telephone system) standard provides an inquiry procedure, which allows the user to locate a mobile telecommunications device without involving the user when sending an emergency call. It becomes.
[0003]
In addition to emergency calls, the location of mobile telecommunications equipment is desirable in some circumstances.
From WO 97/23104, a method for transmitting an emergency call of a mobile telecommunications device to an emergency call center in a PCS1900 mobile radio system is known. In this method, for example, “9-1-1” in response to an emergency rescue request. The location data of the mobile radio subscriber is transmitted as necessary.
From US 5,388,147 an emergency call method in a cellular telecommunication system is known, in which the location data of the mobile radio device making the call is transmitted to the emergency call center only after the establishment of a digital radio channel.
[0004]
It is an object of the present invention to provide a method and mobile telecommunications network for transmitting an emergency call of a mobile telecommunications device that can speed up the location of the mobile telecommunications device .
[0005]
A problem related to a method of transmitting an emergency call is a method of transmitting an emergency call of a mobile telecommunications device in a UMTS mobile telecommunications network, and in a first step, a serving radio network controller (SRNC) In the second step, after the successful identification of the inquiry from the serving radio network controller, the confirmation of the inquiry is made to the remote communication device by setting the signal RRC connection. In the third step, the remote communication device confirms the establishment of the RRC connection with the serving radio network controller with the completion of the message RRC connection setting by the remote communication device, and makes an emergency call to the current position of each mobile telecommunications device. Mobile telecommunications before sending or during emergency call sending A mobile switching center (Mobile switching station) that is not dependent on other components of the network, is transmitted to the serving radio network controller in the third step with the completion of the message RRC connection, and is subsequently connected to the serving radio network controller. Solved by a method of sending an emergency call of a mobile telecommunications device, establishing a direct connection between the telecommunications device and a Location Service Call Client via a -service Switching Center.
This greatly reduces the time to implement the emergency call message by transmitting the location of each subscriber device that sends the emergency call simultaneously with the start of the emergency call message. In this case, the mobile telecommunications device need not wait for a request for a location.
A problem related to a mobile telecommunications network is that an RRC connection is made from a mobile telecommunications device to a serving radio network controller in a mobile telecommunications network having a mobile telecommunications device, a serving radio network controller, a mobile switching center and a location service call client. After the request RRC connection request is transmitted and the identification of the inquiry is successful from the serving radio network controller, the confirmation of the inquiry is returned to the mobile telecommunications device by the signal RRC connection setting, and the message RRC is sent by the telecommunications device. Upon completion of the connection setup, the establishment of the RRC connection with the serving radio network controller is confirmed, and the current position of each mobile telecommunications device is determined by the mobile telecommunications network before or during the transmission of the emergency call. Required without depending on another component, Sage RRC connection is completed and transmitted to the serving radio network controller, and the connection between the telecommunication equipment and the location service call client is established by the mobile switching center connected to the serving radio network controller. Solved by telecommunications network.
Advantageous embodiments are described in claims 2 to 7.
[0006]
If the location of the mobile telecommunications equipment is known prior to sending an emergency call, which may be made, or is determined during an emergency call without relying on another component of the mobile telecommunications network, In the emergency call inquiry procedure, it is no longer necessary to determine the position by means of azimuth measurements of the mobile telecommunications equipment by means of multiple transmitters. Therefore, the transmission of emergency calls is very quick and in addition the reliability is improved. This is because the connection between the mobile telecommunications equipment and other components in the mobile telecommunications network, for example, a fixed transmitter, is poor in some circumstances. The method of the present invention can be applied to any type of mobile telecommunications equipment, such as terminal equipment, or distribution equipment in ships or vehicles, or other telecommunications equipment.
[0007]
A particularly reliable position detection is possible if this position detection is carried out completely without the involvement of the respective user, for example with a regular time clock. In this case, it is always guaranteed that the position is detected when the need to output an emergency call signal occurs. This position detection should not be much earlier, so the time clock should be set narrower.
[0008]
In order to be able to perform position detection in advance even in remote places, position detection can be performed not only via a fixed transmission device, but also using, for example, another mobile telecommunications device.
[0009]
In this case, the position signal can be transmitted together with the emergency call notification without any user action.
[0010]
Position detection without the use of other components of the mobile telecommunications network is possible, for example, by the global positioning system (GPS) of each mobile telecommunications device equipped with a corresponding module.
[0011]
Further advantages and features of the invention arise from the embodiments of the subject of the invention which are shown in the drawings and described below. Here, FIG. 1 is a schematic configuration of position detection in the UMTS standard. FIG. 2 is a routine protocol for emergency calls in the UMTS standard. FIG. 3 is a progress schema relating to an emergency call in the configuration of the present invention. FIG. 4 is a principle diagram of the position detection method showing a plurality of fixed transmission devices and mobile telecommunications equipment in an overhead view.
[0012]
In the first embodiment, the location of the mobile telecommunications equipment UE is detected before the emergency call is sent.
[0013]
Here, for the purpose of illustration, an emergency call conventional progress protocol (FIG. 2 suggests the UMTS standard in the Entwicklungsstufe release 99) is shown.
[0014]
The emergency call is initiated by an inquiry 1 of the mobile telecommunications equipment UE (user equipment) which already contains information which is here an emergency call. This can be done, for example, by manual operation by the user or by an automatic mechanism such as an accident detector.
[0015]
In the first three steps to be executed first, the connection between the mobile telecommunications equipment UE and the control unit SRNC (Serving Radio Network Controller) depends on the RRC (Radio Ressource Control) protocol. Established.
[0016]
Inquiry 1 (RRC connection request) relating to connection establishment is transmitted to a control unit SRNC (serving radio network control unit) included in the remote communication network TN. This control unit SRNC manages and controls a plurality of transmitters S1, S2, S3 ..., also indicated as Node B, and therefore also monitors a plurality of mobile radio cells. A unit consisting of one (S) RNC and a plurality of Node Bs is called a radio network system (RNS) as shown in FIG. A plurality of RNS are integrated into UTRAN (Universal Terrestrial Radio Access Network).
[0017]
After the identification of the inquiry 1 is successful, the control unit SRNC returns the inquiry 1 to the remote communication device UE that has made the inquiry by a signal 2 (RRC connection setup) that is common for confirmation and connection establishment. Is done.
[0018]
In a third step, this telecommunications device UE confirms the establishment of the connection with message 3 (RRC connection complete), so the RRC connection between the control unit SRNC and the mobile telecommunications device UE is Has been established.
[0019]
In the next two steps, a connection with an MSC (Mobile-services Switching Center) is established, which represents the interface between the fixed network and the mobile network. The abbreviation 3G-MSC used in FIG. 1 represents a third generation MSC.
[0020]
With the message 4 (CM Service Request), the mobile telecommunications equipment UE first inquires about the connection with the interface MSC, which is inquired of the control unit SRNC. Based on this, the control unit SRNC transmits an inquiry 5 (RANAP CM Service Request) to the interface MSC by the protocol RANAP (Radio Access Network Application Part). The MSC also checks whether the location of the mobile telecommunications device UE is reliable in the first place, on the other hand, the component HLR (FIG. 1) determines whether the mobile telecommunications device UE supports the location service in the first place. Inspect.
[0021]
In the sixth step, on the one hand, a connection is established between the mobile telecommunications equipment UE and the respective location service station (LCS client), eg fire department, police, private public safety service, etc.
[0022]
At this point, despite the fact that the time has already passed since the establishment of the connection between the mobile telecommunications equipment UE and the location station (LCS client) was relatively complicated in several steps, The location of mobile telecommunications equipment has not been performed.
[0023]
For the first time in the seventh step, a signal 7 (RANAP Location Reporting Control) is received from the Mobile Service Switching Center MSC as a request that the mobile telecommunications equipment UE should perform location detection. It is transmitted to the controller SRNC.
[0024]
In the eighth step, the actual position of the mobile telecommunications device UE is detected. This position detection is performed, for example, according to the elapsed time method, in which various fixed transmission devices S1, S2, S3 transmit data to the mobile telecommunications equipment UE, and from the elapsed time of the respective data, the UE's The distances to the transmission devices S1, S2 and S3 are determined.
[0025]
The position of the mobile telecommunications equipment UE thus determined can be transmitted, and in a new step, an interface between the mobile network and the fixed network with a signal 9 (RANAP Location Report), That is, it is transmitted to the mobile service station MSC.
[0026]
In the next step of the passage of time, a MAP Subscriber Location Report is sent as a message 10 from the MSC to a so-called GMLC (Gateway Mobile Location Center). This report includes, for example, the identifier of the mobile telecommunications device UE, the location of the mobile telecommunications device UE, and the time that has elapsed since the last position detection.
[0027]
As a confirmation from the GMLC, a signal 11 (MAP Subscriber Location ack) is returned to the MSC.
[0028]
Subsequently, as the message 12 (position information), information on the current position is transmitted to the LCS client already prepared for reception of the position information by the preceding message 8, that is, the fire department or the like.
[0029]
The current emergency call is terminated with a subsequent message 13 (Emergency Call Release) from the location service client (LCS client) to the mobile telecommunications equipment UE, and the system is released for another emergency call. The
[0030]
Message 14 and message 15 further monitor the termination of the current emergency call between the GMLC and the service station MSC.
[0031]
On the other hand, according to the present invention, if the location of the UE is known by the mobile telecommunications device UE before the emergency service call is started or by the user of the mobile telecommunications device UE, Can be modified and thus significantly shortened.
[0032]
In this case, the current position of the mobile telecommunications device is already transferred with the message 3 from the mobile telecommunications device UE to the control device SRNC of the transmitting devices S1, S2, S3. This controller forwards the location directly to the location service call (LCS) client, ie the fire department. The mobile telecommunications equipment UE does not have to wait for a position detection request. The structure of message 3 (RRC connection setup complete) of the embodiment according to the present invention is shown in FIG. Here, it is clear that the position data is already included.
[0033]
The prior position detection can be performed by the following method at regular time intervals, for example.
[0034]
In the first method, for example, a cell signal (so-called cell signal) that identifies each cell in which a transmitting device is present in a remote communication device UE whose position is to be determined at a distance from each fixed transmitting device S1 such as a radio tower. Cell ID) is sent out. When this signal is received by the mobile telecommunications device existing in the cell, the position of the mobile telecommunications device in the cell, that is, in the reception area of the transmitting device, is confirmed. However, since such cells are greatly expanded, position detection is limited in terms of accuracy.
[0035]
Especially in the East Asian region, the mode is reduced to about 1.28 Mchips / s compared to the TDD mode having a normal transmission rate of 3.84 Mchips / s, so-called TDSCDMA (time division synchronous code division multiple access) mode. Another method is used for position detection, which uses directed signal transmission and determines the transmission direction by measuring the elapsed time of the signal between the transmitting device and the mobile telecommunications equipment UE. At the same time, the position of the mobile telecommunications device UE can also be calculated. The transmission direction is determined via a so-called smart antenna, which allows the directed radiation and reception of data. These smart antennas need to be provided in both the fixed transmitter and the mobile telecommunications equipment UE.
[0036]
In another very advantageous method, the transmitting device sends data in predetermined blocks. Here, the predetermined block is simply temporarily occupied by data, for example, synchronization data, and remains in a state of being temporarily vacant as a window. In this window phase (idle time slot), the mobile telecommunications equipment UE does not need to receive a signal from the transmitter S1. Therefore, this suspension period can be used for the mobile telecommunications equipment UE to receive signals from the other transmitters S2, S3. Therefore, in this phase, the mobile telecommunication equipment UE can receive the position signals P2, P3 from the other transmitters S2, S3 and is therefore azimuthally measured by a plurality of transmitters S1, S2, S3 at the same time.
[0037]
The other transmission devices S2 and S3 transmit the same signal sequence as the transmission device S1. Therefore, the time slot of the transmitting device S2 or S3 starts simultaneously with this time slot in the signal sent from the transmitting device S1. Whenever a window remains in the signal sequence transmitted from S1 in a corresponding time slot, it is possible to receive a corresponding signal contained in the same designated time slot of the transmitting device S2 or S3. These transmitters do not occupy the time slot with one signal at each transmission, but the time slot is regular or irregular in order to be able to receive signals from other transmitters. Are free as idle slots in different orders.
[0038]
The mobile telecommunications equipment UE evaluates the reception time point of the signal in each time slot of another transmission device (for example, S2, S3) received in each vacant time slot of a certain transmission device (for example, S1). Thereby, the mobile telecommunication device UE detects a time difference Δt1 between the start of the time slot and the reception time of the signal of the transmitting device S1 belonging to this time slot. The remote communication device UE notifies this value to the transmission device S1. Similarly, a time difference Δt2 between the start of the time slot and the reception of the signal belonging to the transmission device S2 is detected when the transmission device S1 is stopped, and this time difference is notified. Correspondingly, a time difference Δt3 between the start of the time slot and the reception of the corresponding signal of the transmitting device S3 is detected and notified to the transmitting device S1.
[0039]
The so-determined value of the signal delay is used by the transmitting device S1 to calculate the exact position of the mobile telecommunications device UE. For this purpose, differences Δt12 = Δt1−Δt2 and Δt13 = Δt1−Δt3 are formed, respectively. From this difference, the position of the mobile telecommunications device UE is detected as the intersection of the hyperbolas A2 and A3 (FIG. 4). This hyperbolic course results from the known positions of the transmitters S2 and S3 and from Δt12 and Δt13.
[0040]
When the signal propagation speed is known, the distance from the signal elapsed time Δt1 to the transmission device S1 of the mobile telecommunications device UE is known. Accordingly, the position of the mobile telecommunications device can be obtained from the set SM of intersections of the distance circle A1 and the time difference hyperbolic curves A2 and A3 centered on the transmission device S1 (FIG. 4). The intersection set SM represents the location of the mobile telecommunications equipment.
[0041]
By knowing the location and transmitting this location simultaneously with the start of the emergency call message, the time to implement the emergency call message is greatly reduced.
[0042]
In the second embodiment, the location is determined while sending an emergency call, but this is done in a manner that does not depend on another component of the mobile telecommunications network TN. For this purpose, GPS (Global positioning system) is used for position detection. Therefore, an accuracy of about 20 m can be achieved. Although it is necessary to provide a GPS unit in the mobile telecommunications device UE, this makes it possible to perform position detection very quickly, and without depending on the mobile telecommunications network TN, for example, transmitters S1, S2, S3. .. can also be performed when the signal reception state is poor.
[0043]
Therefore, speeding up the transmission of emergency calls is also achieved when using GPS while transmitting emergency calls. It can be seen that position detection using GPS can likewise be performed in advance with a regular time clock, in which case the position detection data can be stored and used during an emergency call.
[Brief description of the drawings]
FIG. 1 is a schematic configuration of position detection in the UMTS standard.
FIG. 2 is a routine protocol for emergency calls in the UMTS standard.
FIG. 3 is a progress scheme relating to an emergency call in the configuration of the present invention.
FIG. 4 is a principle diagram of a position detection method.

Claims (8)

A method for transmitting an emergency call of a mobile telecommunications equipment (UE) in a UMTS mobile telecommunications network, comprising:
In the first step, a request RRC connection request (1) relating to establishment of an RRC connection is transmitted to a serving radio network controller (Serving Radio Network Controller, SRNC),
In the second step, after the identification of the inquiry (1) is successful from the serving radio network controller (SRNC), confirmation of the inquiry is returned to the remote communication device (UE) by the signal RRC connection setting (2). ,
In the third step, the remote communication device (UE) confirms the establishment of the RRC connection with the serving radio network controller with the message RRC connection setup completion (3), and the current position of each mobile telecommunications device Without relying on another component of the mobile telecommunications network before sending the emergency call or during the transmission of the emergency call, and with the completion of the message RRC connection already serving radio in the third step To the network controller,
A direct connection between the telecommunications equipment and the location service call client (LCS client) is subsequently established by a mobile switching center (MSC) connected to the serving radio network controller. A method of transmitting an emergency call of a mobile telecommunications device. The method of claim 1, wherein the position is determined according to regular settings without depending on a user of the mobile telecommunications device. The method according to claim 1, wherein the regular setting is position detection based on a temporal clock. The method according to any one of claims 1 to 3, wherein the mobile telecommunications device detects a position using a global positioning system (GPS). The method according to claim 1, wherein the position detection is performed by an elapsed time method. 6. The method according to claim 5, wherein the elapsed time of the signals of the various fixed transmitters is determined in the window time (idle slot) of at least one other transmitter. 7. A method according to claim 5 or 6, wherein the elapsed time of the signal of another mobile telecommunications device that regularly performs unique position detection is used for position detection. In a mobile telecommunications network (TN) having a mobile telecommunications equipment (UE), a serving radio network controller (SRNC), a mobile switching center (MSC) and a location service call client,
A request RRC connection request (1) related to establishment of an RRC connection is transmitted from the mobile telecommunications equipment (UE) to the serving radio network controller (SRNC),
After successful identification of the query (1) from the serving radio network controller (SRNC), a confirmation of the query is sent back to the mobile telecommunications equipment (UE) by signal RRC connection setup (2),
The remote communication device (UE) confirms the establishment of the RRC connection with the serving radio network controller (SRNC) with the message RRC connection setup completion (3), and the current mobile remote communication device (UE) A location is determined without depending on another component of the mobile telecommunications network (TN) before or during the transmission of the emergency call, and the serving radio network control with the completion of the message RRC connection Part (SRNC),
A connection between the telecommunications equipment (UE) and the location service call client (LCS client) is established by the mobile switching center (MSC) connected to the serving radio network controller (SRNC). A mobile telecommunications network (TN) characterized in that

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